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Testing a Claim About a Mean:  Not Known

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1 Testing a Claim About a Mean:  Not Known
Section 8-5 Testing a Claim About a Mean:  Not Known

2 Notation = sample mean m = claimed population mean (from H0)
n = sample size = sample mean m = claimed population mean (from H0) s = sample standard deviation

3 Requirements for Testing Claims About a Population Mean (with  Not Known)
1) The value of the population standard deviation  is not known. 2) Either or both of these conditions is satisfied: The population is normally distributed or n > 30.

4 Test Statistic for Testing a Claim About a Mean (with  Not Known)
x – µ t = s n P-values and Critical Values Found in Table A-3 or by calculator Degrees of freedom (df) = n – 1

5 Example: People have died in boat accidents because an obsolete estimate of the mean weight of men (166.3 lb) was used. A random sample of n = 40 men yielded the mean = lb and standard deviation s = lb. Do not assume that the population standard deviation  is known. Test the claim that men have a mean weight greater than lb.

6 Example: Requirements are satisfied:  is not known, sample size is 40 (n > 30) We can express claim as  > lb It does not contain equality, so it is the alternative hypothesis. H0:  = lb null hypothesis H1:  > lb alternative hypothesis (and original claim)

7 Example: Let us set significance level to  = 0.05 Next we calculate t
df = n – 1 = 39 area of 0.05, one-tail yields critical value t = 1.685;

8 Example: t = does not fall in the critical region bounded by t = 1.685, we fail to reject the null hypothesis.  = 166.3 or z = 0 t = 1.52 Critical value t = 1.685

9 Example: Final conclusion:
Because we fail to reject the null hypothesis, we conclude that there is not sufficient evidence to support a conclusion that the population mean is greater than lb.

10 Normal Distribution Versus Student t Distribution
The critical value in the preceding example was t = 1.782, but if the normal distribution were being used, the critical value would have been z = The Student t critical value is larger (farther to the right), showing that with the Student t distribution, the sample evidence must be more extreme before we can consider it to be significant.

11 P-Value Method Use software or a TI-83/84 Plus calculator.
If technology is not available, use Table A-3 to identify a range of P-values (this will be explained in Section 8.6)

12 Testing hypothesis by TI-83/84
Press STAT and select TESTS Scroll down to T-Test press ENTER Choose Data or Stats. For Stats: Type in m0: (claimed mean, from H0) x: (sample mean) sx: (sample st. deviation) n: (sample size) choose H1: m ≠m <m >m0 (two tails) (left tail) (right tail) Page 218 of Elementary Statistics, 10th Edition.

13 (continued) Press on Calculate Read the test statistic t=… and the P-value p=…

14 Testing a Claim About a Standard Deviation or Variance
Section 8-6 Testing a Claim About a Standard Deviation or Variance

15 Notation n = sample size s = sample standard deviation
s2 = sample variance  = claimed value of the population standard deviation (from H0 ) 2 = claimed value of the population variance (from H0 )

16 Requirements for Testing Claims About  or  2
1. The sample is a simple random sample. 2. The population has a normal distribution. (This is a much stricter requirement than the requirement of a normal distribution when testing claims about means.)

17 Chi-Square Distribution
Test Statistic

18 Critical Values for Chi-Square Distribution
Use Table A-4. The degrees of freedom df = n –1.

19 Table A-4 Table A-4 is based on cumulative areas from the right.
Critical values are found in Table A-4 by first locating the row corresponding to the appropriate number of degrees of freedom (where df = n –1). Next, the significance level  is used to determine the correct column. The following examples are based on a significance level of  = 0.05.

20 Critical values Right-tailed test: needs one critical value
Because the area to the right of the critical value is 0.05, locate 0.05 at the top of Table A-4.

21 Critical values Left-tailed test: needs one critical value
With a left-tailed area of 0.05, the area to the right of the critical value is 0.95, so locate 0.95 at the top of Table A-4.

22 Critical values Two-tailed test: needs two critical values
Critical values are two different positive numbers, both taken from Table A-4 Divide a significance level of 0.05 between the left and right tails, so the areas to the right of the two critical values are and 0.025, respectively. Locate and at top of Table A-4

23 Critical values for a two-tailed test

24 Finding a range for P-value
A useful interpretation of the P-value: it is observed level of significance. Compare your test statistic c2 with critical values shown in Table A-4 on the line with df=n-1 degrees of freedom. Find the two critical values that enclose your test statistic. Determine the significance levels a1 and a2 for those two critical values. Your P-value is between a1 and a (see examples below)

25 Examples: Right-tailed test: If the test statistic c2 is between critical values corresponding to the areas a1 and a2 , then your P-value is between a1 and a2 . Left-tailed test: If the test statistic c2 is between critical values corresponding to the areas 1-a1 and 1-a2 , then your P-value is between a1 and a2 .

26 Examples: Two-tailed test: If the test statistic c2 is between critical values corresponding to the areas a1 and a2 , then your P-value is between 2a1 and 2a2 . Two-tailed test: If the test statistic c2 is between critical values corresponding to the areas 1-a1 and 1-a2 , then your P-value is between 2a1 and 2a2 . (Note: for two-tailed tests, multiply the areas by two)

27 Finding the exact P-value by TI-83/84
Use the test statistic c2 and the calculator function c2 cdf to compute the area of the tail: c2 cdf(teststat,999,df) gives the area of the right tail (to the right from the test statistic) c2 cdf(-999,teststat,df) gives the area of the left tail (to the left from the test statistic) Multiply the area of the tail by 2 if you have a two-tailed test


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